High-efficiency tea drying device for tea processing

Abstract

The application discloses a kind of high-efficiency tea drying device for tea processing, and technical solution main points are as follows: including: box, the top of box is equipped with feed pipe, the bottom of box is equipped with two discharge pipes;Two side limit plates are arranged in the inside of box, two side limit plates are connected with baffle, the bottom of baffle is connected with two vertical boards;Tea is transported and dried in batches by multiple frames and frame bodies, a part of tea is rotated after moving to preset position with frame body, tea is again in the upper part of tea pile when returning to material cavity, multiple frames and frame bodies move along with wheel belt reciprocating, the angle of two guide plates can be rotated when baffle moves to preset position, so that guide plate is in inclined state, a part of tea under tea pile can slide along guide plate to discharging channel, and is released to corresponding frame body, so that a pile of tea raw materials can be dried in batches, and the uniformity of drying is guaranteed.

Description

Technical Field

[0001] This invention relates to the field of tea processing technology, and specifically to a high-efficiency tea drying device for tea processing. Background Technology

[0002] Tea leaves refer to the leaves or buds of the tea plant. Generally, tea refers to a beverage made from the leaves of the tea plant, which can be brewed directly with boiling water. Tea belongs to the dicotyledonous plant family, comprising approximately 30 genera and 500 species, distributed in tropical and subtropical regions. China has 14 genera and 397 species, mainly produced south of the Yangtze River. Among them, the genera *Tea* and *He* are of great economic value. Tea contains catechins, cholesterol, caffeine, inositol, folic acid, pantothenic acid, and other components that can improve human health.

[0003] In the tea production process, drying is required. Current technologies either use drawer-type drying boxes with sieve frames placed at intervals inside the drying box and baked using electricity, but the temperature near the door of the sieve frame is lower than the temperature inside, resulting in uneven drying; or use stirring-type drying drums, but when stirring and dispersing the tea, the stirring leaves collide with the dried tea leaves and easily break the tea leaves, causing additional losses and resulting in poor quality tea after drying. Summary of the Invention

[0004] To address the shortcomings of existing technologies, this invention provides a high-efficiency tea drying device for tea processing, aiming to alleviate the aforementioned problems to at least some extent.

[0005] The above-mentioned technical objective of the present invention is achieved through the following technical solution:

[0006] A high-efficiency tea drying device for tea processing, comprising:

[0007] The box body has an inlet pipe at the top and two outlet pipes at the bottom.

[0008] Two side limiting plates are provided on the inside of the box on both sides, and a partition is connected between the two side limiting plates. Two vertical plates are connected to the bottom of the partition.

[0009] Two tires are located inside the box, forming a material cavity between the two tires, and a material discharge channel is formed between the vertical plate and the tires;

[0010] Two baffles are provided on both sides of the partition, and one end of the baffles contacts the tire.

[0011] Multiple frames are mounted on the belt, and each frame has a support for holding tea leaves. The top of each support has multiple drying openings.

[0012] Multiple arc-shaped top rods are located inside the housing;

[0013] Two guide plates are located at the top of the partition;

[0014] A movable component is disposed between the partition and the vertical plate, and is used to move the position of the baffle to open the material discharge channel when the frame moves to the first preset position;

[0015] A rotating component is disposed between the baffle and the guide plate, and is used to rotate the guide plate by an angle when the baffle moves to a preset position;

[0016] A hot air component, located on the housing, is used to generate hot air and deliver it into the frame.

[0017] A drive component is located between the housing and the tire, and is used to reciprocate the tire.

[0018] Preferably, the moving component includes a sliding opening on one side of the vertical plate, a slider slidably connected in the sliding opening, a push block on one side of the slider, a side opening on one side of the partition, a baffle slidably connected in the side opening, a first spring connected between the baffle and the side opening, a first traction rope connected to the bottom of the slider, and one end of the first traction rope passing through the sliding opening and the side opening and connected to the baffle.

[0019] Preferably, the slider has a connection port inside, and a gear is rotatably connected inside the connection port. A first rack is slidably connected to the connection port on one side of the push block. The first rack meshes with the gear. A second spring is connected between the slider and the push block. A insertion interface is provided on one side of the first rack. A communication port communicating with the connection port is provided on the top of the slider. A second rack meshing with the gear is slidably connected inside the communication port. The second rack is slidably fitted with the insertion interface. A third spring is connected between the second rack and the communication port.

[0020] Preferably, the bottom of the push block is rotatably connected to a roller.

[0021] Preferably, a transverse opening is provided on one side of the push block, penetrating the push block and the slider. A top contact rod is slidably connected in the transverse opening. A rubber pad is provided at one end of the top contact rod inside the slider. A fourth spring is connected between the rubber pad and the top contact rod. Stop blocks are respectively connected to the upper and lower sides of the top contact rod. A fifth spring is connected between the stop blocks and the slider. An abutment piece is connected to the bottom of the frame.

[0022] Preferably, the rotating component includes a connecting plate disposed between the two guide plates, a spring telescopic rod connected between the connecting plate and the partition, a sliding plate rotatably connected to the bottom of each of the two guide plates, a first contact rod connected to one side of the sliding plate, a connecting opening communicating with the side opening on the top of the partition, the first contact rod slidably connected in the connecting opening, a second contact rod connected to one side of the baffle, and a preset distance between the second contact rod and the first contact rod.

[0023] Preferably, the hot air component includes a hot air blower connected to one side of the housing, with a pipe connected to the air outlet of the hot air blower. One end of the pipe passes through the housing and the side limiting plate and extends into the interior of the tire. A conveying port is provided on one side of the tire. The conveying port passes through the tire and the frame and extends into the frame body. A corrugated pipe fitted with the conveying port is connected inside the frame body.

[0024] Preferably, a fixed shaft is connected to one side of the inner side of the frame, the frame body is rotatably connected to the fixed shaft, a sixth spring is connected between the frame body and the frame, a sliding groove is provided on one side of the side limiting plate, a sliding rod is slidably connected in the sliding groove, a seventh spring is connected between the sliding rod and the sliding groove, and the arc-shaped top rod is connected to the sliding rod.

[0025] Preferably, an electric push rod is connected to the top of the box body, the telescopic shaft of the electric push rod is connected to the feed pipe, a guide shaft is connected to one side of the side limiting plate, and a second traction rope is connected to one side of the feed pipe. The second traction rope passes around the guide shaft and is connected to the slide rod.

[0026] Preferably, the driving component includes a plurality of wheel axles rotatably connected to the housing, the wheel axles being sleeved with the wheel belts, drive motors being connected to both sides of the housing, and a chain connecting the drive shaft of the drive motor to an adjacent wheel axle.

[0027] In summary, the present invention has the following main beneficial effects:

[0028] By setting up a driving component, the reciprocating rotation of the drive belt causes multiple frames and their supporting structures to move along the belt's trajectory. When a frame moves to a first preset position, i.e., within the material drop channel, a moving component can move the position of the baffle. This baffle movement opens the material drop channel, allowing the tea leaves to fall into it and be caught by a frame and its supporting structure. After the frame moves out of the material drop channel, the baffle... The plate can be reset to prevent tea leaves from falling into the cavity that has not yet moved into the material feeding channel, ensuring that the tea leaves remain in the feeding cavity. Hot air from the hot air unit enters the frame and dries the tea leaves on it. When the frame moves to the second preset position, i.e., the position of the arc-shaped top rod, the arc-shaped top rod contacts the frame, causing the frame to rotate under the constraint of the arc-shaped top rod. As the frame continues to move, it maintains its rotating posture as it passes the arc-shaped top rod, allowing the tea leaves on the frame to fall back into the feeding cavity. In this process, multiple frames and racks are used to convey and dry tea leaves in batches. A portion of the tea leaves moves with the racks to a preset position and then rotates. When the tea leaves return to the material chamber, they are positioned above the tea pile. The multiple frames and racks move back and forth with the tires. The rotating component can rotate the angle of two guide plates when the baffle moves to the preset position, allowing the guide plates to tilt. A portion of the tea leaves below the tea pile can slide along the guide plates to the discharge channel and be released onto the corresponding rack. This allows for batch drying of a batch of tea raw materials, ensuring uniform drying and preventing the problem of some tea leaves drying faster than others due to the direction of hot air blowing. In addition, compared to agitated drying drums, this application allows the tea leaves to fall freely onto the racks while drying a batch of tea raw materials, without excessive hard interference with the position of the tea leaves. It also prevents the tea leaves from colliding with each other due to the agitator needing to disperse the tea leaves, thus avoiding losses exceeding the preset amount. This solves the problem of poor tea quality after drying in existing tea drying equipment. Attached Figure Description

[0029] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0030] Figure 2 This is a schematic diagram of the box structure of the present invention;

[0031] Figure 3 yes Figure 2 Enlarged schematic diagram of the local structure at point A;

[0032] Figure 4 This is a schematic diagram of the side limiting plate structure of the present invention;

[0033] Figure 5 This is a schematic diagram of the wheel and belt shaft structure of the present invention;

[0034] Figure 6 This is a schematic diagram of the connection port structure of the present invention;

[0035] Figure 7 This is a schematic diagram of the transverse opening structure of the present invention;

[0036] Figure 8 This is a schematic diagram of the frame structure of the present invention;

[0037] Figure 9 This is a schematic diagram of the rotating component structure of the present invention;

[0038] Figure 10 This is a schematic diagram of the arc-shaped top rod structure of the present invention.

[0039] Figure label:

[0040] 100. Box body; 101. Feed pipe; 102. Discharge pipe; 103. Side limiting plate; 104. Partition plate; 105. Vertical plate; 106. Tire; 107. Material cavity; 108. Material drop channel; 109. Baffle plate; 110. Frame; 111. Frame body; 112. Drying port; 113. Arc-shaped top rod; 114. Guide plate;

[0041] 200. Sliding opening; 201. Slider; 202. Push block; 203. Side opening; 204. First spring; 205. First traction rope;

[0042] 300. Connecting port; 301. Gear; 302. First rack; 303. Second spring; 304. Insertion port; 305. Connecting port; 306. Second rack; 307. Third spring; 308. Roller;

[0043] 400. Lateral opening; 401. Top contact rod; 402. Rubber pad; 403. Fourth spring; 404. Stop block; 405. Fifth spring; 406. Abutment piece;

[0044] 500. Connecting plate; 501. Spring telescopic rod; 502. Slide plate; 503. First contact rod; 504. Connecting opening; 505. Second contact rod;

[0045] 600. Hot air blower; 601. Pipeline; 602. Conveying port; 603. Corrugated pipe;

[0046] 700. Fixed shaft; 701. Sixth spring; 702. Slide groove; 703. Slide rod; 704. Seventh spring; 705. Electric push rod; 706. Guide shaft; 707. Second traction rope; 708. Wheel belt axle; 709. Drive motor; 710. Chain. Detailed Implementation

[0047] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0048] refer to Figures 1-10 A high-efficiency tea drying device for tea processing, comprising:

[0049] The box body 100 has a feed pipe 101 at the top and two discharge pipes 102 at the bottom.

[0050] Two side limiting plates 103 are provided on both sides of the inside of the box 100. A partition 104 is connected between the two side limiting plates 103. Two vertical plates 105 are connected to the bottom of the partition 104.

[0051] Two tires 106 are located inside the housing 100, and a material cavity 107 is formed between the two tires 106. A material drop channel 108 is formed between the vertical plate 105 and the tires 106.

[0052] Two baffles 109 are provided on both sides of the partition 104, and one end of the baffle 109 contacts the tire 106;

[0053] Multiple frames 110 are mounted on the belt 106. Each frame 110 has a frame 111 for receiving tea leaves. Multiple drying openings 112 are provided on the top of the frame 111.

[0054] Multiple arc-shaped top rods 113 are located inside the housing 100;

[0055] Two guide plates 114 are located on top of the partition 104;

[0056] A movable component is located between the partition 104 and the vertical plate 105, and is used to open the material discharge channel 108 by moving the position of the baffle 109 when the frame 110 moves to the first preset position.

[0057] A rotating component is disposed between the baffle 109 and the guide plate 114, and is used to rotate the angle of the guide plate 114 when the baffle 109 moves to a preset position.

[0058] A hot air component, located on the housing 100, is used to generate hot air and deliver it into the frame 111.

[0059] A drive component is located between the housing 100 and the belt 106 for reciprocating rotation of the belt 106;

[0060] By setting up the feed pipe 101, during use, the operator can put the tea raw materials to be dried into the box 100 through the feed pipe 101. The tea leaves can fall into the material cavity 107 and be received by the guide plate 114 and the baffle 109. Specifically, the operator can start the drive component, which reciprocates the rotating belt 106. The rotation of the belt 106 can drive the multiple frames 110 and the frame bodies 111 on the belt 106 to move. The frames 110 and the frame bodies 111 move along the track of the belt 106. When the frame 110 moves to the first preset position, that is, into the material drop channel 108, the position of the baffle 109 can be moved by the moving component. The movement of the baffle 109 can open the material drop channel. In channel 108, the tea leaves are no longer blocked by the baffle 109 and fall into the feeding channel 108. They are received by a frame 110 that moves into the feeding channel 108 and the frame body 111 on the frame 110. After the frame 110 moves out of the feeding channel 108, the baffle 109 can return to its original position to prevent the tea leaves from falling into the cavity that has not yet moved into the feeding channel 108, ensuring that the tea leaves remain in the feeding cavity 107. Hot air from the hot air component enters the frame body 111 and dries the tea leaves on the frame body 111. When the frame 110 moves to the second preset position, i.e., the position of the arc-shaped top rod 113, the arc-shaped top rod 113 can contact the frame body 111 on the frame 110. 11. Restricted by the arc-shaped top rod 113, the frame 111 can rotate. As the frame 111 continues to move, it maintains its rotating posture when passing the arc-shaped top rod 113. The tea leaves supported on the frame 111 can fall into the return chamber 107. The multiple frames 110 and the frame 111 convey and dry the tea leaves in batches. A portion of the tea leaves moves with the frame 111 to a preset position and then rotates. When the tea leaves return to the return chamber 107, they will be above the tea pile. The multiple frames 110 and the frame 111 move back and forth with the tire 106. The rotating component can rotate the angle of the two guide plates 114 when the baffle 109 moves to the preset position, allowing the guide plates 114 to be tilted. In this configuration, a portion of the tea leaves below the tea pile can slide along the guide plate 114 to the discharge channel 108 and be released onto the corresponding frame 111. This allows for batch drying of a pile of tea raw materials, ensuring uniform drying and preventing the problem of some tea leaves drying faster than others due to the direction of the hot air blowing. Furthermore, compared to a stirring-type drying drum, this application allows the tea leaves to fall freely onto the frame 111 while drying a pile of tea raw materials, without excessive hard interference with the position of the tea leaves. This prevents the tea leaves from colliding with each other due to the stirring rod's need to disperse them, thus avoiding losses exceeding the preset amount. This solves the problem of poor tea quality after drying in existing tea drying equipment.

[0061] As a further embodiment of the present invention, the moving component includes a sliding opening 200 opened on one side of the vertical plate 105, a slider 201 slidably connected in the sliding opening 200, a push block 202 provided on one side of the slider 201, a side opening 203 opened on one side of the partition plate 104, a baffle 109 slidably connected in the side opening 203, a first spring 204 connected between the baffle 109 and the side opening 203, a first traction rope 205 connected to the bottom of the slider 201, and one end of the first traction rope 205 passing through the sliding opening 200 and the side opening 203 and connected to the baffle 109;

[0062] By setting a push block 202, which extends a sliding opening 200, when the frame 110 moves within the material discharge channel 108 to below the push block 202, the frame 110 can contact the push block 202. As the frame 110 continues to move upward, it can drive the push block 202 and the slider 201 to move. The movement of the slider 201 can pull the first traction rope 205. The first traction rope 205 pulls the position of the baffle 109, allowing the baffle 109 to be displaced. This achieves the purpose of moving the baffle 109 to open the material discharge channel 108 when the frame 110 moves to the first preset position. At the same time, the vertical plate 105 ensures that the tea leaves will not fall to the bottom of the box 100.

[0063] As a further embodiment of the present invention, the slider 201 has a connection port 300 inside, and a gear 301 is rotatably connected inside the connection port 300. A first rack 302 is connected to one side of the push block 202 and is slidably connected to the connection port 300. The first rack 302 meshes with the gear 301. A second spring 303 is connected between the slider 201 and the push block 202. A insertion interface 304 is opened on one side of the first rack 302. A communication port 305 communicating with the connection port 300 is opened on the top of the slider 201. A second rack 306 meshing with the gear 301 is slidably connected inside the communication port 305. The second rack 306 is slidably sleeved with the insertion interface 304. A third spring 307 is connected between the second rack 306 and the communication port 305.

[0064] By setting a second rack 306, when the frame 110 drives the push block 202 to move, the first rack 302 can drive the slider 201 to move upward. When the slider 201 moves upward to a preset position, the second rack 306 can contact the top of the sliding opening 200. The frame 110 drives the push block 202 and the slider 201 to continue to move upward. The second rack 306 moves relative to the slider 201, causing the gear 301 to rotate. The rotation of the gear 301 can cause the first rack 302 and the push block 202 to move. The push block 202 gradually leaves the frame 110 and can retract into the sliding opening 200. This allows the frame 110 to drive the slider 201 to move within the material discharge channel 108 while the push block 202 does not affect the frame 110 leaving the material discharge channel 108.

[0065] As a further embodiment of the present invention, a roller 308 is rotatably connected to the bottom of the push block 202;

[0066] By setting roller 308, the friction generated when push block 202 moves on frame 110 can be reduced.

[0067] As a further embodiment of the present invention, a transverse opening 400 is provided on one side of the push block 202, which penetrates the push block 202 and the slider 201. A top contact rod 401 is slidably connected in the transverse opening 400. A rubber pad 402 is provided at one end of the top contact rod 401 inside the slider 201. A fourth spring 403 is connected between the rubber pad 402 and the top contact rod 401. A stop block 404 is connected to the upper and lower sides of the top contact rod 401 respectively. A fifth spring 405 is connected between the stop block 404 and the slider 201. An abutment piece 406 is connected to the bottom of the frame 110.

[0068] By setting the top contact rod 401, after the slider 201 moves to its limit position within the sliding opening 200, the push block 202 leaves the top of the frame 110. The push block 202 moves through the stop block 404, which can drive the top contact rod 401 to move. The frame 110 continues to move, and one side of the frame 110 can press the position of the top contact rod 401. The top contact rod 401, through the force of the fifth spring 405, can make the rubber pad 402 contact the sliding opening 200, and the friction of the rubber pad 402 pressing the sliding opening 200 restricts the current position of the slider 201, so as to ensure that the baffle 109 is still retracted within the side opening 203. The set abutment piece 406 can ensure that the top contact rod 401 can still be pressed after the frame 110 leaves the top contact rod 401, thus avoiding the problem that when the frame 110 moves to one side of the baffle 109 but has not reached the position of the side opening 203, the slider 201 loses its strength and no longer pulls the first traction rope 205, causing the baffle 109 to reset prematurely and blocking the operation of the frame 110.

[0069] As a further embodiment of the present invention, the rotating component includes a connecting plate 500 disposed between two guide plates 114, a spring telescopic rod 501 connected between the connecting plate 500 and the partition plate 104, a sliding plate 502 rotatably connected to the bottom of each of the two guide plates 114, a first contact rod 503 connected to one side of the sliding plate 502, a connecting opening 504 communicating with the side opening 203 at the top of the partition plate 104, the first contact rod 503 slidably connected in the connecting opening 504, a second contact rod 505 connected to one side of the baffle plate 109, and a preset distance between the second contact rod 505 and the first contact rod 503;

[0070] By setting a second contact rod 505, the second contact rod 505 can be moved when the baffle 109 moves. When the second contact rod 505 moves to a preset position, it can contact the first contact rod 503. As the baffle 109 continues to move, the second contact rod 505 can drive the first contact rod 503 to move. The movement of the first contact rod 503 can drive the slide plate 502 to move. The slide plates 502 at the bottom of the two guide plates 114 move closer to each other. The connecting plate 500 is limited by the set spring telescopic rod 501, which allows the guide plate 114 to rotate around the connecting plate 500 as the center. This achieves the purpose of allowing the guide plate 114 to rotate when the baffle 109 moves to the preset position, and pouring the tea leaves on the top of the guide plate 114 onto the frame 111.

[0071] As a further embodiment of the present invention, the hot air component includes a hot air blower 600 connected to one side of the housing 100. A pipe 601 is connected to the air outlet of the hot air blower 600. One end of the pipe 601 passes through the housing 100 and the side limiting plate 103 and extends into the interior of the tire 106. A conveying port 602 is provided on one side of the tire 106. The conveying port 602 passes through the tire 106 and the frame 110 and extends into the frame 111. A corrugated pipe 603 fitted with the conveying port 602 is connected inside the frame 111.

[0072] By setting up a hot air blower 600, the hot air blower 600 can be turned on during use. The hot air generated by the hot air blower 600 can enter the tire 106 through the pipe 601. The air in the tire 106 is blocked by the side limiting plate 103. The hot air can enter the frame 111 through the conveying port 602 and the corrugated pipe 603, and is blown onto the tea leaves through the drying port 112 opened on the frame 111, which can achieve the purpose of hot air drying of the tea leaves. At the same time, the top of the frame 111 is stepped, which makes it convenient for the tea leaves to adhere to the frame 111, and also makes it convenient for the tea leaves to fall smoothly into the material cavity 107 after the frame 111 rotates.

[0073] As a further embodiment of the present invention, a fixed shaft 700 is connected to one side of the inner side of the frame 110, the frame body 111 is rotatably connected to the fixed shaft 700, a sixth spring 701 is connected between the frame body 111 and the frame 110, a sliding groove 702 is provided on one side of the side limiting plate 103, a sliding rod 703 is slidably connected in the sliding groove 702, a seventh spring 704 is connected between the sliding rod 703 and the sliding groove 702, and an arc-shaped top rod 113 is connected to the sliding rod 703;

[0074] By setting a fixed shaft 700, the fixed shaft 700 and the sixth spring 701 can limit the position of the frame 111. When the frame 110 drives the frame 111 to move upward until it contacts the arc-shaped top rod 113, the frame 111 can rotate around the fixed shaft 700 as a circle while it continues to move, thus achieving the purpose of rotating the frame 111 to tilt the tea leaves on the frame 111. After the tea leaves are dried, the discharge pipe 102 can be opened and the position of the slide rod 703 can be moved so that the slide rod 703 drives the arc-shaped top rod 113 to move. When the frame 111 moves, it is no longer affected by the arc-shaped top rod 113. After the wheel belt 106 turns and moves to the preset position, the tea leaves can be tilted into the discharge pipe 102 and guided out of the box 100 by the discharge pipe 102.

[0075] As a further embodiment of the present invention, an electric push rod 705 is connected to the top of the box 100, the telescopic shaft of the electric push rod 705 is connected to the feed pipe 101, a guide shaft 706 is connected to one side of the side limiting plate 103, and a second traction rope 707 is connected to one side of the feed pipe 101. The second traction rope 707 passes around the guide shaft 706 and is connected to the slide rod 703.

[0076] By setting an electric push rod 705, when the tea leaves need to be unloaded after drying, the feed pipe 101 can be opened and the position of the feed pipe 101 can be moved downward by the electric push rod 705. The downward movement of the feed pipe 101 can allow the slide rod 703 and the arc-shaped top rod 113 to leave the frame 111 through the second traction rope 707. The downward movement of the feed pipe 101 can make the feed pipe 101 act as a limit, so that the tea leaves can fall smoothly into the material cavity 107 by the limit of the feed pipe 101 when feeding.

[0077] As a further embodiment of the present invention, the driving component includes a plurality of wheel shafts 708 rotatably connected to the housing 100, the wheel shafts 708 being sleeved with the wheel belt 106, and drive motors 709 being connected to both sides of the housing 100 respectively, and a chain 710 being connected between the drive shaft of the drive motor 709 and an adjacent wheel shaft 708.

[0078] By setting up a drive motor 709, the drive motor 709 can be started. The rotation of the drive shaft of the drive motor 709 can cause the pulley shaft 708 to rotate through the chain 710. The rotation of the pulley shaft 708 can drive the pulley 106 to rotate, thereby achieving the purpose of making the pulley 106 reciprocate to drive the frame 110 to move.

[0079] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A high-efficiency tea drying device for tea processing, characterized in that, include: The box body has an inlet pipe at the top and two outlet pipes at the bottom. Two side limiting plates are provided on the inside of the box on both sides, and a partition is connected between the two side limiting plates. Two vertical plates are connected to the bottom of the partition. Two tires are located inside the box, forming a material cavity between the two tires, and a material discharge channel is formed between the vertical plate and the tires; Two baffles are provided on both sides of the partition, and one end of the baffles contacts the tire. Multiple frames are mounted on the belt, and each frame has a support for holding tea leaves. The top of each support has multiple drying openings. Multiple arc-shaped top rods are located inside the housing; Two guide plates are located at the top of the partition; A movable component is disposed between the partition and the vertical plate, and is used to move the position of the baffle to open the material discharge channel when the frame moves to the first preset position; A rotating component is disposed between the baffle and the guide plate, and is used to rotate the guide plate by an angle when the baffle moves to a preset position; A hot air component, located on the housing, is used to generate hot air and deliver it into the frame. A drive component is located between the housing and the tire, and is used to reciprocate the tire.

2. The high-efficiency tea drying device for tea processing according to claim 1, characterized in that, The moving component includes a sliding opening on one side of the vertical plate, a slider slidably connected in the sliding opening, a push block on one side of the slider, a side opening on one side of the partition, a baffle slidably connected in the side opening, a first spring connected between the baffle and the side opening, a first traction rope connected to the bottom of the slider, and one end of the first traction rope passing through the sliding opening and the side opening and connected to the baffle.

3. The high-efficiency tea drying device for tea processing according to claim 2, characterized in that, The slider has a connection port inside, and a gear is rotatably connected inside the connection port. A first rack is slidably connected to the connection port on one side of the push block. The first rack meshes with the gear. A second spring connects the slider and the push block. A insertion interface is provided on one side of the first rack. A communication port communicating with the connection port is provided on the top of the slider. A second rack meshing with the gear is slidably connected inside the communication port. The second rack is slidably fitted with the insertion interface. A third spring connects the second rack and the communication port.

4. The high-efficiency tea drying device for tea processing according to claim 2, characterized in that, The bottom of the pusher is rotatably connected to a roller.

5. The high-efficiency tea drying device for tea processing according to claim 3, characterized in that, A transverse opening is provided on one side of the push block, which passes through the push block and the slider. A top contact rod is slidably connected in the transverse opening. A rubber pad is provided at one end of the top contact rod inside the slider. A fourth spring is connected between the rubber pad and the top contact rod. Stop blocks are respectively connected to the upper and lower sides of the top contact rod. A fifth spring is connected between the stop blocks and the slider. An abutment piece is connected to the bottom of the frame.

6. The high-efficiency tea drying device for tea processing according to claim 5, characterized in that, The rotating component includes a connecting plate disposed between the two guide plates, a spring telescopic rod connected between the connecting plate and the partition, a sliding plate rotatably connected to the bottom of each of the two guide plates, a first contact rod connected to one side of the sliding plate, a connecting opening communicating with the side opening on the top of the partition, the first contact rod slidably connected in the connecting opening, a second contact rod connected to one side of the baffle, and a preset distance between the second contact rod and the first contact rod.

7. The high-efficiency tea drying device for tea processing according to claim 1, characterized in that, The hot air component includes a hot air blower connected to one side of the housing. A pipe is connected to the air outlet of the hot air blower. One end of the pipe passes through the housing and the side limiting plate and extends into the interior of the tire. A conveying port is opened on one side of the tire. The conveying port passes through the tire and the frame and extends into the frame body. A corrugated pipe fitted with the conveying port is connected inside the frame body.

8. The high-efficiency tea drying device for tea processing according to claim 1, characterized in that, A fixed shaft is connected to one side of the inner side of the frame, and the frame body is rotatably connected to the fixed shaft. A sixth spring is connected between the frame body and the frame. A sliding groove is opened on one side of the side limiting plate. A sliding rod is slidably connected in the sliding groove. A seventh spring is connected between the sliding rod and the sliding groove. The arc-shaped top rod is connected to the sliding rod.

9. The high-efficiency tea drying device for tea processing according to claim 8, characterized in that, An electric push rod is connected to the top of the box. The telescopic shaft of the electric push rod is connected to the feed pipe. A guide shaft is connected to one side of the side limiting plate. A second traction rope is connected to one side of the feed pipe. The second traction rope passes around the guide shaft and is connected to the slide rod.

10. The high-efficiency tea drying device for tea processing according to claim 1, characterized in that, The drive component includes multiple wheel axles rotatably connected to the housing, the wheel axles being sleeved with the wheel belts, drive motors being connected to both sides of the housing, and a chain connecting the drive shaft of the drive motor to an adjacent wheel axle.

Images